It has taken me years to discover how to actually do this without fighting mind and body. It has never been easy, but it now is.
The real secret is making your digestive biome alkaline. By doing that i am able to eat my last solid food on Sunday night and not have breakfast until Wednesday evening and that by choice. I am not hungry anytime in between and have no cravings.
I have lost all my fat overhead and now bottom at 173 pounds. I still have visceral fat of around several pounds which is another trick i have not tackled yet but should get me to 165 on an almost six foot frame.
Thus i have a weekly fasting surge to stimulate cellular revitalization.
The bottom line is that i can coach anyone in how to do all this and even make it painless unless you face a medical driver that blocks best practice. I have actually solved such a case as well.
Eat less, live longer
Salk scientists show how caloric restriction prevents negative effects of aging in cells
The illustration represents the ways in which caloric restriction affects various aspects of cellular function, with the overall result of reducing inflammation and the activity of many aging-related genes.
February 27, 2020
The bottom line is that i can coach anyone in how to do all this and even make it painless unless you face a medical driver that blocks best practice. I have actually solved such a case as well.
Eat less, live longer
Salk scientists show how caloric restriction prevents negative effects of aging in cells
The illustration represents the ways in which caloric restriction affects various aspects of cellular function, with the overall result of reducing inflammation and the activity of many aging-related genes.
February 27, 2020
https://www.salk.edu/news-release/eat-less-live-longer/?
LA JOLLA—If you want to reduce levels of inflammation throughout your body, delay the onset of age-related diseases and live longer—eat less food. That’s the conclusion of a new study by scientists from the US and China that provides the most detailed report to date of the cellular effects of a calorie-restricted diet in rats. While the benefits of caloric restriction have long been known, the new results show how this restriction can protect against aging in cellular pathways, as detailed in Cell on February 27, 2020.
“We already knew that calorie restriction increases life span, but now we’ve shown all the changes that occur at a single-cell level to cause that,” says Juan Carlos Izpisua Belmonte, co-corresponding author of the new paper, a professor in Salk’s Gene Expression Laboratory and holder of the Roger Guillemin Chair. “This gives us targets that we may eventually be able to act on with drugs to treat aging in humans.”
Aging is the highest risk factor for many human diseases, including cancer, dementia, diabetes and metabolic syndrome. Caloric restriction has been shown in animal models to be one of the most effective interventions against these age-related diseases. And although researchers know that individual cells undergo many changes as an organism ages, they have not known how caloric restriction might influence these changes.
In the new paper, Belmonte and his collaborators—including three alumni of his Salk lab who are now professors running their own research programs in China—compared rats who ate 30 percent fewer calories with rats on normal diets. The animals’ diets were controlled from age 18 months through 27 months. (In humans, this would be roughly equivalent to someone following a calorie-restricted diet from age 50 through 70.)
At both the start and the conclusion of the diet, Belmonte’s team isolated and analyzed a total of 168,703 cells from 40 cell types in the 56 rats. The cells came from fat tissues, liver, kidney, aorta, skin, bone marrow, brain and muscle. In each isolated cell, the researchers used single-cell genetic-sequencing technology to measure the activity levels of genes. They also looked at the overall composition of cell types within any given tissue. Then, they compared old and young mice on each diet.
Credit: Salk Institute
Many
of the changes that occurred as rats on the normal diet grew older
didn’t occur in rats on a restricted diet; even in old age, many of the
tissues and cells of animals on the diet closely resembled those of
young rats. Overall, 57 percent of the age-related changes in cell
composition seen in the tissues of rats on a normal diet were not
present in the rats on the calorie restricted diet.
“This approach
not only told us the effect of calorie restriction on these cell types,
but also provided the most complete and detailed study of what happens
at a single-cell level during aging,” says co-corresponding author
Guang-Hui Liu, a professor at the Chinese Academy of Sciences.
Some
of the cells and genes most affected by the diet related to immunity,
inflammation and lipid metabolism. The number of immune cells in nearly
every tissue studied dramatically increased as control rats aged but was
not affected by age in rats with restricted calories. In brown adipose
tissue—one type of fat tissue—a calorie-restricted diet reverted the
expression levels of many anti-inflammatory genes to those seen in young
animals.
“The primary discovery in the current study is that the
increase in the inflammatory response during aging could be
systematically repressed by caloric restriction” says co-corresponding
author Jing Qu, also a professor at the Chinese Academy of Sciences.
Credit: Salk Institute
“People
say that ‘you are what you eat,’ and we’re finding that to be true in
lots of ways,” says Concepcion Rodriguez Esteban, another of the paper’s
authors and a staff researcher at Salk. “The state of your cells as you
age clearly depends on your interactions with your environment, which
includes what and how much you eat.”
The team is now trying to
utilize this information in an effort to discover aging drug targets and
implement strategies towards increasing life and health span.
Other
researchers on the study were Shuai Ma, Shuhui Sun, Lingling Geng,
Moshi Song, Wei Wang, Yanxia Ye, Qianzhao Ji, Zhiran Zou, Si Wang and Qi
Zhou of the Chinese Academy of Sciences; Xiaojuan He, Wei Li, Piu Chan
and Weiqi Zhang of Xuanwu Hospital Capital Medical University; Xiao Long
of Peking Union Medical College Hospital; and Guoji Guo of Zhejiang
University School of Medicine.
The work and researchers involved
were supported by grants from the National Key Research and Development
Program of China, the Strategic Priority Research Program of the Chinese
Academy of Sciences, the National Natural Science Foundation of China,
Beijing Natural Science Foundation, Beijing Municipal Commission of
Health and Family Planning, Advanced Innovation Center for Human Brain
Protection, the State Key Laboratory of Membrane Biology, the Moxie
Foundation, and the Glenn Foundation.
DOI: DOI: 10.1016/j.cell.2020.02.008
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